JPH04204B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a method and apparatus for measuring the solids load of a centrifuge drum used in a regeneration facility, in particular for separating undissolved solid particles in a nuclear fuel solution.

In regeneration facilities, it is necessary to constantly monitor the amount of solids present in the centrifuge drum for operational reasons and for fissile material monitoring reasons. Monitoring and detection of the amount of solids must be possible both while the centrifuge is rotating and when it is stopped.

Various methods are already known for detecting solid loads in centrifuges.

In one method, twisting of the shaft of a centrifuge drum is detected by means of elongation measurement conditions arranged on the shaft. The amount of torsion is a measure of the amount of solid loading.

In another method, the elastic deformation of the centrifuge drum caused by the centrifugal force acting on the drum envelope is detected at a constant rotational speed using an elongation measuring device mounted on the surface of the drum. Ru. In this case as well, elastic deformation is used as a measure of the amount of solid load.

Furthermore, the amount of solids load is determined by the time it takes for the drum to start from zero rotation speed and reach the operating rotation speed, or vice versa, or the time it takes for the drum to reach zero rotation speed from the operating rotation speed, or the time it takes for the drum to reach the rotation speed from the operating rotation speed to zero, or the time it takes for the drum to reach the rotation speed from the operating rotation speed to zero. It has become known to measure and detect the time elapsed over a range.

Measuring the current consumption of centrifuge drives has also been used to detect solids loading on centrifuge drums.

A very simple and often used method is to measure the weight of the entire centrifuge before and after the centrifugation operation; this can be done by providing a suitable scale on the centrifuge stand. It is possible to implement. At this time, the difference in measured values directly indicates the solids load.

These known methods possess various drawbacks.

Measuring torsion using elongated measuring strips
Provides solid load information only in the acceleration phase.
Measuring the elastic deformation of centrifuge drums with elongated measuring strips makes it possible to measure or monitor the solids load continuously, but, like the methods described above, the measurement can be carried out in a non-contact manner. It has the disadvantage of not being done. Furthermore, when sensing the elastic deformations of the centrifuge drum, in some regeneration installations a sensor (elongation measuring strip) must be accommodated in the reaction space, which is a particular disadvantage.

The two methods described above cannot be measured when the centrifuge is stopped. Moreover, these two methods are not very accurate.

Measuring the time until the rotation of the drum reaches a constant speed or decreases to a constant speed or measuring the current consumption of the centrifuge drive is still an inaccurate method. Furthermore, measurement is not possible when the centrifuge is stopped. Measuring centrifuge weight directly is relatively inaccurate. This is because the weight of a centrifuge is relatively large relative to the solids load.

The object of the present invention is to provide a method and a device for measuring the solids load of a drum of a centrifuge, thereby avoiding the above-mentioned disadvantages of the known methods and, in particular, reducing the reaction time with low outlay in measurement technology. The goal is to enable non-contact measurements outside the space. Furthermore, the measuring method and measuring device of the invention are designed in such a way that the solids load can be measured continuously, both when the centrifuge is stopped and when it is in operation.

The above object is achieved by the characteristic method and device defined in claims 1 and 6.

The procedure according to the invention makes it possible in practice to continuously and reliably monitor or measure the solids load of a centrifuge. Measurements can be performed whether the centrifuge is rotating or stopped. Measuring the frequencies of the natural oscillations that occur ensures a high accuracy of the measurement results and is relatively simple to carry out. The measuring device can be easily mounted outside the reaction space of the regeneration facility. The measuring method of the present invention and the measuring device of the present invention have a wide range of applications.

Characteristic and advantageous modifications of the method and apparatus according to claims 1 and 6 of the invention are indicated in the embodiment section of the claims.

The invention is explained in more detail in the accompanying drawings, which schematically show examples of embodiments.

In the accompanying drawings, identical components are labeled with the same symbols.

The accompanying drawing shows a centrifuge 2 with a centrifuge drum 4, which is driven by an electric motor 14 via a mounted drive shaft 8, a V-belt pulley 10 and a V-belt 12. being driven.

The drum 4 of the centrifuge is arranged in a suspended manner, which is expedient when used in nuclear fuel regeneration installations. In principle, other arrangements (upright arrangement, horizontal or inclined arrangement) are of course also possible.

The centrifugal drum has an inlet 16 and an outlet 18. These inlets and outlets serve, especially in regeneration facilities, to separate solid particles from the fuel solution. When the centrifuge drum 4 rotates, solid particles settle on the inner wall of the centrifuge drum and form a solid load 20, also referred to as a cake.

The problem is detecting the amount of this solids load. For this purpose, an additional mass m ₂ of a rotating body 24, for example in the form of a cage, is mounted at the upper end 22 of the drive shaft 8, which rotating body is part of an electric machine 26 with a solid-state coil 28. .

The drum 4 of the centrifuge has a first mass m ₁ ,
A cage-shaped rotating body _{2 as a second mass m 2 which} is elastically coupled to this mass m 1 via a drive shaft 8
4 forms a dynamic two-mass vibration system.

An electromotive force is generated for a short time in the cage-shaped rotating body 24 (mass m ₂ ) via the stator coil 28 of the electric machine 26, and this electromotive force causes a torsional moment to be generated in the vibration system for a short time. m ₁ and m ₂ , and the torsional moment is converted into a natural torsional vibration. The frequency of this vibration is the additional mass m ₂ (cage-shaped rotating body 2
4) and the mass m ₁ of the centrifuge drum and changes if these masses change, and thus on the solids load of the drum 4 of the centrifuge. Therefore, the amount of solid load 20 can be detected by measuring the frequency of the generated torsional vibration.

The frequency can be measured using an electromagnetic or optical measuring sensor 3.
0, this sensor has an additional mass m ₂ of
That is, the mark 32 attached to the rotating body 24 in the shape of a cage is scanned. The frequency of the output signal of the measurement sensor is detected and evaluated by the device 34.
The measurement result or detected solid load is sent to the notification device 36.
It is indicated by.

Further possibilities are shown diagrammatically in the attached figures.

The cage-shaped rotating body 24 does not have to be attached to the end of the drive shaft 8. This rotating body can be provided at any desired location, for example at the location shown at 24' in FIG.

The additional mass of the rotating body in the form of a cage can also be mounted, for example, as shown in FIG. be. This additional axis or axis 38 is connected via a protruding platelet 40 to
A second one is located near the outlet 18 of the centrifuge drum 4 or as an extension of the drive shaft.
It is formed as shown in the figure. Additional axis or axis 3
8 can be additionally supported (bearing 44).

The additional mass m ₂ with markings 32 can also simply be formed as a disk 46 (as shown in FIGS. 2 and 3), in which case the torsional moment for generating torsional vibrations can be controlled, for example The brake jaws 50 of this device can be actuated by a pressure medium via a pressure medium source 54 on a valve 52 or simply mechanically brought into contact with the disc 46 . It will be done.

It is also possible to generate the torsional moment via the drive motor 4 of the centrifuge 4, which motor is provided with an additional coil 56 which can be supplied with electricity. The rotational moment of the motor is changed for a short period of time.

In some cases, it is also possible to omit the additional mass m ₂ . The torsional vibration system in this case consists of a centrifuge drum 4 and a drive shaft 8 or an additional shaft or axis 38, on which a scanning mark 58 is mounted as shown in FIG.
The torsional moment is generated in this case, for example, by mechanically bringing the two braking elements 60, 62 into contact for a short period of time. The scanning of the mark 58 and the evaluation of what has been detected by the measuring sensor takes place as already described above.

As mentioned above, in addition to the generation and evaluation of torsional vibrations, which is most advantageous from the point of view of measurement technology and cost, it is also possible in principle to generate and evaluate longitudinal and/or bending vibrations. .

[Brief explanation of drawings]

FIG. 1 shows a particularly excellent first embodiment of the present invention.
FIG. 2 shows two variants of the embodiment shown in FIG. 1, and FIG. 3 shows another embodiment of the invention. In the figure, 4... drum of a centrifuge, 8...
... Drive shaft, 14 ... Drive motor, 22 ... Upper end of drive shaft, 24, 24' ... Rotating body, 26 ... Electric machine, 30 ... Measurement sensor, 32 ... Mark,
34...Evaluation device, 36...Notification device, 38...
Shaft or axis line, 42...extension portion, 46...disk,
48... Braking device, 60, 62... Braking element, 5
6...Coil, 58...Mark, _m1 ...Mass of centrifuge drum, _m2 ...Additional mass of rotating body.

Claims (1)

[Claims] 1. A method for measuring the solids load of a centrifuge drum used in a regeneration facility, in particular for separating undissolved solid particles in a nuclear fuel solution. ₁ and an additional mass m ₂ , 24, 46, connected to the drum 4, m ₁
A mechanical vibration system consisting of 38 m ₁ , m ₂
is placed in the natural vibration state of the system and the frequency of the natural vibration or the quantity derived from the frequency depending on the solid load is measured and an evaluation of the solid load is made. 2. A method according to claim 1, characterized in that the vibration system is placed in a state of torsional vibration. 3. The method according to claim 2, wherein the torsional vibration is generated by changing (decelerating or accelerating) the rotational moment or rotational speed of the drum 4 of the centrifugal separator for a short period of time. . 4. Torsional vibrations are generated by mechanically braking for a short time the rotational movement of the drive member of the drum 4 of the centrifuge or the members 24, 46, 38 that rotate together with the drum and are fixed to the drum. Claim 2 or 3, characterized in that
The method described in section. 5. The method according to claim 2 or 3, wherein the torsional vibration is applied non-contactly to the vibration system for a short period of time by an electromagnetic field. 6. Centrifuge drum 4, m ₁ and drum 4, m ₁ of a centrifuge used in particular in regeneration installations to separate undissolved solid particles in nuclear fuel solutions. A mechanical oscillating system m ₁ , m ₂ consisting of additional masses m ₂ , 24, 46, 38 connected to is placed in the natural vibration state of the system and whose frequency of natural vibration or In a measuring device for carrying out a method in which quantities derived from the vibration frequency are measured and an evaluation of the solids load is made, a drum m ₁ , 4 of a centrifuge and an additional mass m ₂ , 24 connected to the drum are provided. , 46, 38, a device 26, 48, 60, 62 for transferring the mechanical vibration system m ₁ , m ₂ to a natural vibration state, and measuring and evaluating the frequency of the natural vibration or a quantity derived from the frequency. A device characterized in that it is provided with devices 30, 34, and 36. 7. Device according to claim 6, characterized in that the additional mass m ₂ is formed by the drive member of the centrifuge drum 4 or the drive shaft 8 of the centrifuge drum 4. 8 The additional mass m ₂ is an additional shaft 38 which is mutually non-rotatably fixed to the drum 4 of the centrifuge, this shaft being arranged on the opposite side of the drive shaft 8 with respect to the drum 4 of the centrifuge. characterized by having
An apparatus according to claim 6 or 7. 9. Device according to claim 8, characterized in that the additional shaft is an extension of the drive shaft. 10. Claim 6, characterized in that the additional mass m ₂ is formed by an object fixed in a mutually non-rotatable manner to the drive shaft 8 of the drum 4 of the centrifuge or to the additional shaft 38. 9. A device according to any one of paragraphs 9 to 9. 11. Device according to claim 10, characterized in that the objects that are non-rotatably fixed to each other are the rotor or rotating body 24 of an electric machine 26. 12 Objects that are non-rotatably fixed to each other are located at the end 2 of the drive shaft 8 remote from the centrifuge drum 4.
2 or an additional axis or axis 38
The device according to item 1. 13 Mechanical vibration system consisting of a centrifuge drum 4 and an additional mass m ₂ connected to the drum
m ₁ , m ₂ are one device 26, 48, 60, 62
Claims 6 to 12 are characterized in that the device is capable of transitioning to a torsional vibration state due to
Equipment described in any one of the preceding paragraphs. 14. The device for transferring the mechanical oscillation system into a torsional oscillation state is an electric machine 26 which, by means of its electrically excited magnetic field, can be arranged on the drive shaft 8 or on an additional shaft or axis 38. 14. Device according to claim 13, characterized in that a torsional moment is imparted to the rotor or rotating body 24. 15 The device for shifting the mechanical oscillation system into a torsional oscillation state is formed by an additional separately energized coil 56 of the electric motor 14 driving the drum 4 of the centrifuge, with which the oscillation system can be moved into a torsional oscillation state. The claimed invention is characterized in that it is possible to form an electrically excited magnetic field that realizes a change in rotational speed (deceleration or acceleration) that causes a torsional moment to act on m ₁ and m ₂ for a short time. The device according to scope item 13. 16 The device for shifting the mechanical vibration system to a torsional vibration state is a mechanical braking device 4 that can be contacted for a short time.
8, 60, 62, the braking device comprises a part of the drive or an additional shaft or axis 38 or an object 24, 24', arranged on the drive shaft 8 or the additional shaft or axis 38. 14. Device according to claim 13, characterized in that it acts on 46, 38. 17 The frequency measuring device 30, 34, 36 possesses a measuring sensor 30 which scans the markings 32, 58 attached to the additional mass m ₂ connected to the drum 4 of the centrifuge; The output signal from is sent to an evaluation device 34 for detecting the frequency of the natural vibration of the vibration system m ₁ , m ₂ and for detecting the solids load of the drum of the centrifuge derived from this frequency. Device according to any one of claims 6 to 16, characterized in that: 18. Device according to claim 17, characterized in that the measurement sensor 30 is an electromagnetic tachometer. 19. Device according to claim 17, characterized in that the measurement sensor 30 is an optical sensor. 20. From claim 17, characterized in that the period time of the output signal from the measuring sensor is measured and evaluated in order to detect the frequency or the change in the frequency of the natural vibration of the vibration system. Apparatus according to any one of the preceding clauses.